Knoten
БесплатноНе проверенEnables coding agents to query and commit to a research graph that remembers failed experiments, ensuring reproducibility and preventing redundant work.
Описание
Enables coding agents to query and commit to a research graph that remembers failed experiments, ensuring reproducibility and preventing redundant work.
README
A research graph that remembers what didn't work.
Each idea is a markdown file in git, marked alive, dead, or retracted. If it died, the node carries the reason, what would bring it back, and the code to reproduce it.
How it works
A graph is a folder. A node is a markdown file: frontmatter for machines, prose for humans, code to reproduce it.
---
id: hyp-self-consistency
type: hypothesis
status: dead
links:
- {rel: kn:killedByGate, to: method-compute-matched-baseline}
repro:
script: experiments/self_consistency.py
model: Qwen3-8B-Instruct
data: GSM8K test, 1319 questions
cmd: python experiments/self_consistency.py --n 5 --temp 0.7
results:
acc_greedy: 0.741
acc_self_consistency: 0.792
acc_compute_matched_baseline: 0.788
tokens_per_question: 1420
n_independent: 1319
---
# Self-consistency (sample 5, majority vote) beats greedy decoding
## Verdict: DEAD
Sampling 5 chains and taking the majority scored 79.2% vs 74.1% greedy. +5.1 points.
It looked like a free win.
## Why it died
It is not free. It costs **5x the tokens**, and given the same budget a longer-CoT
baseline reaches **78.8%**. The entire gain was compute, not method.
```python
# reproduce the kill:
python experiments/self_consistency.py --n 5 --compare compute_matched
```
## What would reopen this
A task where the majority-vote *aggregation* does real work, i.e. where the gain
survives a compute-matched baseline. Plausible for code execution or theorem proving.
GSM8K is not that task.
Three months later, when someone proposes self-consistency again:
$ knoten query "self-consistency"
[✗ DEAD] hyp-self-consistency
killed by : method-compute-matched-baseline
reopen if : A task where the majority-vote aggregation does real work, i.e.
where the gain survives a compute-matched baseline…
Use it
pip install -e . # add ".[mcp]" for the agent server
knoten init my-topic # a new graph (it's a folder)
knoten new hypothesis hyp-idea # scaffold a node with whatever the rules demand
knoten query <term> # has this been tried?
knoten show <node> # edges, results, attachments
knoten attach <node> <file>... # attach a script, plot or notebook
knoten detach <node> <file>
knoten validate # enforce this graph's own rules
knoten path A B # how did we get from A to B?
knoten hook # make `git commit` refuse a broken graph
Each graph declares its own rules in graph.yaml. knoten knows nothing about your
field. It enforces whatever you said matters. The example graph requires every claim to
report tokens_per_question and to rest on at least 30 independent questions; a different
topic would require something else entirely.
rules:
- id: underpowered
when_type: hypothesis
require_result_min: {n_independent: 30}
message: A result on fewer than 30 independent questions is noise, not evidence.
Your graph also declares its own vocabulary, and that is enforced too:
node_types: [hypothesis, experiment, finding, method, source]
statuses: [open, alive, dead, retracted, superseded, active]
type: hypthesis is a typo, not a new type. status: ded is worse than wrong — it would
silently drop the claim out of every query, which is exactly the sort of quiet rot this
tool exists to prevent. Both are now violations.
A rule key — or a config key — knoten doesn't recognise is a hard error, not a
shrug. Config that enforces nothing is decoration, and a rule that enforces nothing is
worse than no rule, because you think you're covered.
knoten new reads those rules and pre-fills exactly what they demand — nothing in the
scaffold is knoten's opinion, it's your graph's. The values are TODO on purpose, so
new + validate is a checklist rather than a guessing game:
$ knoten new hypothesis hyp-my-idea --status dead
+ nodes/hyp-my-idea.md (hypothesis, dead)
pre-filled what THIS graph's rules require:
## Why it died, ## What would reopen this, tokens_per_question, n_independent
The failure this tool exists to prevent was caused by friction, so the write path is where friction hurts most. Write prose, not boilerplate you had to be rejected to discover.
The gate is a git hook
knoten hook # after `git init`
git commit now runs knoten validate and refuses a graph that breaks its own rules:
$ git commit -m "self-consistency is a win"
✗ hyp-self-consistency
[live-claims-must-cite-their-gates] An unchallenged claim is not a finding, it is a hope.
1 violation(s) — commit REJECTED
A rule that only fires when you remember to ask is the rule that let the last attempt rot.
Put it somewhere you can't walk past. (git commit --no-verify bypasses it — you should
have a reason.)
Attach the code and the plots
A node isn't just a claim. It carries what you need to re-run it.
knoten attach hyp-self-consistency experiments/self_consistency.py accuracy_vs_budget.png
The files are copied into attachments/<node-id>/, listed in the frontmatter, and
images are embedded in the node body so they render on GitHub:
attachments/hyp-self-consistency/
self_consistency.py the script that KILLED it
accuracy_vs_budget.png the plot that shows why
knoten validate then fails if a node lists an attachment that isn't there. A broken
repro is a broken node.
knoten show hyp-self-consistency # edges, results, attachments
knoten detach hyp-self-consistency accuracy_vs_budget.png
Two readers, one file
Humans skim the prose and get the story: what was tried, what killed it, what's still open. No database, no UI, just markdown you can read in any editor or on GitHub.
Agents traverse the frontmatter: typed edges (kn:killedByGate, kn:survivedGate),
structured results, a repro block with the exact script/model/data/command, and the
paths of any attached scripts and plots, which they can read and re-run directly. An agent
answers "has this been tried?" and "how do I reproduce it?" without reading a word of
prose.
The same file serves both. That's the whole design.
For coding agents (MCP)
Point Claude Code, or any MCP client, at a graph. It then accumulates knowledge about a topic across sessions instead of starting cold every time:
pip install -e ".[mcp]"
{"mcpServers": {"knoten": {
"command": "knoten-mcp",
"env": {"KNOTEN_GRAPH": "/path/to/llm-research"}
}}}
knoten_query("has anyone tried self-consistency?") ← BEFORE it starts work
knoten_get("hyp-self-consistency") ← the full node, post-mortem included
knoten_commit(node) ← AFTER it finishes, pass or fail
knoten_attach(node, [script, plot]) ← and the code that proves it
knoten_path(a, b) ← how did we get from A to B?
knoten_validate() ← run the graph's own rules
The agent reads the graph before running an experiment and writes back when it's done, including when the experiment fails. A dead hypothesis with a documented cause of death is the most valuable node in the graph, and the one that would otherwise be lost.
It writes back the evidence too, not just the prose: knoten_attach puts the script it
ran and the plot it made into the node. A claim you can't re-run is a claim nobody trusts
in six months — so the agent that killed a hypothesis leaves behind the thing that killed
it, ready for the next agent to run.
knoten_commit validates before writing and refuses on violation — the candidate node
is parsed and checked in memory, so an invalid node never reaches your filesystem. An agent
cannot record a shiny result that cites no test it survived:
{"status": "REJECTED",
"violations": [{"rule": "live-claims-must-cite-their-gates",
"message": "An unchallenged claim is not a finding, it is a hope."}]}
Why bother
You stop redoing experiments you already ran and forgot. Dead ends come back with their cause of death and a command to re-run them.
And you can't fool yourself as easily: a claim can only be marked alive if it cites a test it survived, so a good-looking result that was never checked can't quietly become a finding.
And a broken node is a loud failure, not a quiet one. Unreadable frontmatter, an
unknown edge relation (kn:killdByGate — one letter dropped), a rule key that doesn't
exist: all are errors. A graph that silently drops what it can't parse reports itself
healthy while it rots.
And a claim someone later withdrew says so. query surfaces the retraction from both
sides, so an agent asking "has this been tried?" about a claim that was later retracted
is told it was retracted — not just what the claim said:
[✓ ALIVE] hyp-few-shot-format
survived : method-compute-matched-baseline
RETRACTED by : ret-oops
See examples/llm-research/ for a worked graph and SPEC.md for the design.
MIT. One dependency (PyYAML). The whole thing is a few files you can read in one sitting.
Установка Knoten
У этого сервера нет опубликованного пакета — он собирается из исходников. Открой репозиторий и следуй инструкции в README.
▸ github.com/BY571/knotenFAQ
Knoten MCP бесплатный?
Да, Knoten MCP бесплатный — установка в пару кликов через Unyly без оплаты.
Нужен ли API-ключ для Knoten?
Нет, Knoten работает без API-ключей и переменных окружения.
Knoten — hosted или self-hosted?
Self-hosted: сервер запускается локально на твоей машине командой из раздела установки.
Как установить Knoten в Claude Desktop, Claude Code или Cursor?
Открой Knoten на unyly.org, выбери вкладку своего клиента (Claude Desktop, Claude Code, Cursor) и нажми Install — конфиг сгенерируется автоматически, без правки JSON.
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